Black color generation amount determining method in black printing, a black color generation amount determining apparatus in black printing, a media having recorded thereon a black color generation amount determining program in black printing

ABSTRACT

In order to perform black printing in a color space for printing approximately equivalent element colors such as CMY, a CPU system multiplies an undercolor amount CMYmin which is a common minimum component in the element colors by a predetermined generation ratio BGR to generate a black color component. In this case, the generation ratio BGR of the black color component is made smaller as the data before conversion becomes brighter, whereby a generation amount Kout of the black color component is small for the brighter color if the undercolor amount CMYmin is the same. When the printing operation is performed with reference to a color conversion table for printing obtained in this way, a dot corresponding to the black color component is unremarkable.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a black color generation amountdetermining method in black printing, a black color generation amountdetermining apparatus in black printing and a media having recordedthereon a black color generation amount determining program in blackprinting.

2. Description of the Prior Arts

Various methods have conventionally been proposed for determining ablack color component in performing black printing, one of which isproposed in “Theory and Practice of Black Printer” at ElectrostaticSociety Magazine, Vol. 3, No. 3, pp.67 to 75.

The basic idea of black printing is such that an undercolor amount whichis a common minimum component is obtained based upon tone data ofso-called CMY (cyan, magenta, yellow) to calculate K (black) componentby multiplying the undercolor amount by a constant number called a blackgeneration ratio (BGR), while a predetermined ratio (UCR ratio) ismultiplied to the K component in order to replace the CMY component withthe K component for attaining decreased amount.

On the other hand, Japanese Laid-Open Patent Application No. HEI 7-87347discloses a method for determining an UCR ratio based upon chroma uponperforming such black printing.

Black printing is put to practical use in a color printer connected to acomputer, wherein K dot is marked with CMY dot.

The principal objective in the above-mentioned conventional method fordetermining a black color component is to prevent color difference frombeing generated. A remarkableness of dot is liable to become a problemabove the color difference for a device having a relatively large dotdiameter such as a color printer. On the other hand, there mayfrequently be the case where colors are different from one another evenif they have the same undercolor amount. It has been known that theremarkableness of each K dot is different, when these different colorsare printed by the color printer.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a black colorgeneration amount determining method in black printing capable of makingK dot unremarkable including a color printer.

The black color generation amount determining method in black printingaccording to the present invention is constructed such that, upongenerating a black color component in order to perform black printing ina color space for printing comprising a plurality of approximatelyequivalent element colors, the black color component is caused to begenerated to have a predetermined relationship with respect to a graycomponent in the plurality of element colors, and that the brighter acolor is, the more the generation amount decreases.

In the present invention having the aforesaid construction, the blackcolor component is caused to be generated to have a predeterminedrelationship with respect to the gray component in the plurality ofelement colors upon performing black printing in the color space forprinting comprising the plurality of approximately equivalent elementcolors. The generation amount of the black color component varies notonly in accordance with the gray component, but also in relation tobrightness of data before conversion, that is, the brighter the databefore conversion is, the less the black color component generates.Accordingly, the generation amount of the black color component isdecreased in the brighter color even if the gray component is the same,thereby making the black color component unremarkable.

Therefore, the present invention can provide the black color generationamount determining method capable of making dot unremarkable, since thepresent invention places great importance on not only the viewpoint ofthe color difference but also the viewpoint of the remarkableness of dotin black printing to control the generation amount of the black colorcomponent with respect to a bright color.

Various deciding methods can be adopted to the gray component which isthe basis for generating the black color component. Another object ofthe present invention is to provide a more specific deciding method ofthe gray component.

In the black color amount determining method in black printing accordingto the present invention, the gray component is decided based upon anundercolor amount which is a common minimum component in the pluralityof element colors.

In the present invention having the aforesaid construction, the graycomponent is decided based upon the obtained undercolor amount which isthe common minimum component in the plurality of element colors. Theundercolor amount in a narrow sense corresponds to minimum tone data if,for example, the plurality of element colors are expressed by CMY andthe undercolor amount is afforded as the tone data representing thedensities of CMY. However, the undercolor amount is not limited to theone in a narrow sense. For example, there has been known a method as anundercolor removal in which the undercolor amount obtained in this wayis simply replaced with the black color component for subtracting thecomponent value of each element color by the replaced value. In thiscase, the element color of the minimum component value is originally notutilized at all. However, it has been known that chroma is decreased inthe aforesaid method. Therefore, a method of an undercolor addition mayactually be performed to add a predetermined component amount to each ofthe element colors after subtracting the undercolor amount. Accordingly,an experiential compensation may be added to the undercolor amount, sothat the undercolor amount which is the common minimum component in theplurality of element colors is merely used as the basis of the graycomponent. The present invention includes the undercolor amount suitablyincreased or decreased.

In this way, the present invention can provide the black colorgenerating amount determining method capable of deciding the graycomponent in a relatively simple manner.

It should be noted that the method of the undercolor removal orundercolor addition may be adopted in the present invention. In thiscase, the undercolor removal amount can be varied related to unfixedgeneration amount of the black color component. For example, upongenerating the black color component while determining the undercolorremoval amount for subtracting the component amount of each elementcolor based upon the undercolor amount, the undercolor removal amountmay be determined to be great as the generation amount of the blackcolor component increases. In such a construction, the undercolorremoval amount varies with the variation of the actual generation ratioof the black color component since the generation ratio of the blackcolor component varies in accordance with brightness, whereby thebalance as the undercolor amount is maintained.

Brightness of a color is the basis for determining the generation amountof the black color component. The tendency may show that the brighterthe color is, the more the generation amount decreases. Therefore, thebasis can include the other factors than brightness.

Therefore, further object of the present invention is to provide a blackcolor generation amount determining method in black printing capable ofhaving a basis including other factors than brightness.

The black color generation amount determining method in black printingaccording to the present invention has the construction for deciding byadding chroma as a guideline of bright color to brightness.

In the present invention having such a construction, the greater chromais, the greater the index of brightness is by adding chroma to the indexof brightness, with the result that the generation amount decreases. Onthe other hand, the smaller chroma is, the smaller the index ofbrightness becomes, so that the generation amount increases. When thisconstruction is adopted, the generation amount of the black colorcomponent increases in the portion of nearly gray having low chroma,while it decreases in a bright portion.

Therefore, according to the present invention, the generation amount ofthe black color component increases in the portion of nearly gray havinglow chroma, so that the gray balance is easy to be kept, while thegeneration amount of the black color component is controlled in thebright area by increasing the index of brightness, so that the black dotbecomes unremarkable.

When the generation amount of the black color component is calculatedbased upon brightness, it is necessary to obtain brightness as theassumption. If the objective color space possesses a parameter ofbrightness as the direct element, this parameter can be used. However,on the assumption of the color space for printing comprising a pluralityof approximately equivalent element colors, the parameter of brightnessas the direct element is not be provided.

Therefore, further object of the present invention is to provide asuitable black color generation amount determining method in blackprinting adopting to the case of not providing a parameter of brightnessas the direct element.

The black color generation amount determining method in black printingaccording to the present invention obtains brightness of color withreference to a table on which a corresponding relationship is recordedin advance.

In the present invention having such a construction, the table isprepared on which each brightness of each color is recorded, whereby thegeneration amount of the black color component is determined asdescribed above by obtaining brightness with reference to the table.

Accordingly, brightness can accurately and simply be obtained byreferring the table for brightness of color.

Although the table referred to in this case may be the one capable ofreferring at least for brightness, the table may be referred to for theother parameters such as chroma in addition to brightness. This tablemay always be kept, or may be present only when the generation amount ofthe black color component is determined. Further, this table may beprovided with a corresponding relationship among all colors of the databefore conversion, or may be provided with a corresponding relationshipfor some colors. The corresponding relationship may be calculated by aninterpolation calculation with respect to colors whose correspondingrelationship is not recorded on the table. Further, accessing anexternal data base only in case of necessity is naturally included.

The Neugebauer equation is well-known for a reproducibility of colors byprinting. Although it is generally difficult to realize due to a largecalculation amount, the reproducibility of color can accurately besimulated if the calculation is possible.

Accordingly, further object of the present invention is to provide ablack color generation amount determining method in black printingsuitable for high calculation ability.

The black color generation amount determining method in black printingaccording to the present invention has the construction such that threestimulus values are obtained based upon the Neugebauer equation,whereupon brightness of color is obtained by performing a linearconversion of the three stimulus values.

In the present invention having such a construction, so-called threestimulus values can be obtained based upon the Neugebauer equation evenif high calculation ability is required, whereby brightness can beobtained by the linear conversion if the three stimulus values areobtained.

Therefore, brightness can be obtained only by the calculation accordingto the present invention.

Black printing is performed in a printing stage. However, the imageprocessing or the like is not always executed in the color space in theprinting stage. Accordingly, an operation is frequently performed forcolor-converting the color space in the image processing into the colorspace in the printing stage.

Therefore, further object of the present invention is to provide a blackcolor generating amount determining method in black printing suitablyused upon the operation of the color-conversion from the color space inthe image processing into the color space in the printing stage.

The black color generating amount determining method in black printingaccording to the present invention has the construction such that thegeneration amount of the black color component in the color space forprinting is determined based upon the color data comprising a coordinatevalue of the color space different from that for printing.

In the present invention having such a construction, when the colorspace for printing is CMY, the color data represented by the coordinatevalue from the color space different from that of CMY, such as RGB (red,green, blue) or L*a*b* is used as a parameter to determine thegeneration amount of the black color component in the color space forprinting including the black color component.

Therefore, most preferable generation amount of the black colorcomponent can be determined based upon the color data of the color spacedifferent from that for printing according to the present invention.

Although it is possible in this way to execute the determination of thegeneration amount of the black color component every time the printingoperation is performed, it is enough to execute once the determinationof the generation amount of the black color component to determine theblack color component with respect to each color.

Therefore, further object of the present invention is to provide a blackcolor generating amount determining method in black printing capable ofdecreasing the number of the determining operation of the black colorcomponent.

The black color generating amount determining method in black printingis utilized upon determining the black color component of the colorconversion table used for color-converting from the color spacedifferent from that for printing into the color space for printing.

In the present invention having such a construction, once such a colorconversion table is formed, the same color conversion table may bereferred to for performing the color conversion upon the printingoperation from the other color space.

Therefore, according to the present invention, the black color componentwhose dot is unremarkable is used for forming the color conversiontable, so that the same table can be reused to decrease the operationnumber.

The black color generation amount determining method includes the casewherein the method is independently executed in an apparatus or the casewherein the method is incorporated in other apparatus to be executed asone function of the apparatus. In other words, the concept of theinvention includes various embodiments. Accordingly, it is possible tobe realized not only in a hardware but also in a software.

Therefore, further object of the present invention is to provide a blackcolor generation amount determining apparatus as a hardware forrealizing the concept of the present invention as the hardware.

The black color generation amount determining apparatus according to thepresent invention is the one for determining the generation amount ofthe black color component in order to perform black printing in a colorspace for printing comprising a plurality of approximately equivalentelement colors, wherein the black color component is caused to begenerated to have a predetermined relationship with respect to a graycomponent in the plurality of element colors, and the brighter a coloris, the more the generation amount decreases.

Therefore, the present invention is capable of providing the black colorgeneration amount determining apparatus affording the same effect.

Further, in case where the embodying example of the concept of theinvention is a software for determining the generation amount of theblack color component, it is ought to say that the present invention isnaturally present on a recording media having the software recordedthereon to be utilized.

Accordingly, further object of the present invention is to provide asoftware for determining the generation amount of the black colorcomponent.

A media having recorded thereon the black color generation amountdetermining program according to the present invention is the one havingrecorded thereon the black color generation amount determining programfor determining by a computer the generation amount of the black colorcomponent in order to perform black printing in a color space forprinting comprising a plurality of approximately equivalent elementcolors, wherein the black color component is caused to be generated tohave a predetermined relationship with respect to a gray component inthe plurality of element colors, and the brighter a color is, the morethe generation amount decreases.

Therefore, the present invention is capable of providing the mediahaving recorded thereon the black color generation amount determiningprogram in black printing.

The recording media may be a semiconductor chip, a magnetic recordingmedia or optically magnetic recording media. This concept can be adoptedto any recording media developed from now on in the same manner. Thereis no inquiring that the same concept is adopted to a reproducing stagesuch as a primary reproduction product or secondary reproductionproduct. In addition, the present invention is similarly utilized in thecase of using a communication line as a supplying method.

Additionally, the concept of the invention is not so different when theinvention is realized in partly the software and partly the hardware.Moreover, it may include an embodiment in which a portion of the programof the invention is recorded on the recording media which is read as theneed arises.

The effect of rendering dot unremarkable as described above isdemonstrated upon printing based upon the black color componentdetermined in this way, whereby it should be said that the concept ofthe invention is effective for the color conversion table for printingused upon printing as well as is effective for the method or theapparatus for forming the color conversion table for printing. In thiscase, various types can be adopted for the format as the colorconversion table or referring method. It is unnecessary for the table toalways be usably developed. The table may be developed only when used.Further, the table may be distributed in a common condition and renderedsuitable corresponding to an adopting system when installed.Additionally, although there may be the case where the color conversiontable for printing is not always used in the printing stage, it ispossible in this case to vary the generation amount of the black colorcomponent by using brightness as the index.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a flowchart showing a procedure upon forming a colorconversion table for printing by adopting a black color generationamount determining method according to one embodiment of the presentinvention.

FIG. 2 is a schematic explanatory view showing a eight-pointinterpolation calculation.

FIG. 3 is a schematic explanatory view showing a color screen dot model.

FIG. 4 is a graph showing a relationship between brightness index LS anda generation ratio of K as BGR.

FIG. 5 is a view briefly showing a relationship between brightness indexLS and a generation ratio of K as BGR in a two-dimensional color space.

FIG. 6 is a view briefly showing a state wherein a component afterconversion is obtained from a component before conversion.

FIG. 7 is a view showing a conversion procedure of color conversion.

FIG. 8 is a view showing a constitution of a color conversion table forprinting.

FIG. 9 is a view showing a computer system for forming a colorconversion table for printing.

FIG. 10 is a schematic block diagram showing an image processingprinting system for executing color conversion by using a colorconversion table for printing.

FIG. 11 is a block diagram of a printer.

FIG. 12 is a schematic explanatory view showing in more detail a printhead unit of the printer.

FIG. 13 is a schematic explanatory view showing a state wherein colorink is ejected by the print head unit.

FIG. 14 is a flowchart showing a printing procedure executed in an imageprocessing printing system

DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention will be explained with reference to the drawings.

FIG. 1 is a flowchart showing a schematic procedure upon forming a colorconversion table for printing by adopting a black color generationamount determining method according to one embodiment of the presentinvention.

Firstly, an undercolor value CMYmin is obtained in a first step ST1based upon respective color components CMY. The undercolor value has thesame meaning as an undercolor amount, which represents a common minimumcomponent when respective color components are represented as tone dataat coordinate value in a color space for printing comprising a pluralityof approximately equivalent element colors such as CMY. When therespective color components are 0 to 255, comparing the case whereC:200, M:200, Y:50 to the case where C: 50, M: 50, Y:200, both of theundercolor value CMYmin itself are 50, while a generation ratio of K(BGR) varies as described later.

Brightness L and chroma T are obtained at a second step ST2. Althoughthe brightness L is the minimum necessary value, the chroma T is alsoutilized in order to make it easy to keep a gray balance. When a databefore conversion is represented as CMY, the brightness L and the chromaT cannot be obtained by a simple calculation.

A first method for obtaining the brightness L and the chroma T is theone wherein the brightness L and the chroma T are subject to colorimetryto be obtained in advance, while the obtained values are recorded in atable as a three-dimensional calorimetric data, whereby this table isreferenced. In this case, it is impossible from the viewpoint of thework to perform colorimetry with respect to all of the colors(approximately 16,700,000 colors), so that colorimetry is performed withrespect to some colors, while an interpolation calculation is executedfor those of the other colors to be obtained.

An eight-point interpolation shown in FIGS. 2(a) to (c) is usable as oneexample of the interpolation calculation. In the interpolationcalculation of this eight-point interpolation, with respect to a colorat a coordinate at CMY coordinate axis, a corresponding relationship ofa lattice point which encircles the coordinates is utilized to obtainthe corresponding relationship of the coordinates via the linearinterpolation calculation. It is noted that the color space of the databefore conversion is divided into lattice-like unit cube to obtain thebrightness L and the chroma T at the lattice point by performingcolorimetry.

When the conversion value at the vertex Pk of the order of k of a cubeis designated as Xk and the volume of the cube is designated as V, thecorresponding value Pc at an internal point P of the cube can beinterpolated by weighing due to the ratio of the volume Vk of eightsmall rectangular parallel-epipeds which are divided at P point as shownin the figure.${Pc} = {\sum\limits_{k = 1}^{8}\quad {\left( {{Vk}/V} \right) \cdot {Xk}}}$

The conversion value Xk at this time is the brightness L or the chroma Tat each lattice point, and the obtained corresponding value Pc is thebrightness L or the chroma T at the internal point P.

Another method can be utilized which is adapted to color screen dotmodel for solving the Neugebauer equation.

In the case of printing dots on a paper with color inks of CMY, theoverlapping state of each color on the paper is constituted of eightcolor areas of a first color CMY, a second color CM, MY, YC, a thirdcolor CMY and a white color W as shown in FIG. 3. When each areal ratioof each color ink is represented by f(C), f(M) and f(Y) as well as thesecolor inks randomly overlap with one another on the paper, each of theareal ratio of the above-mentioned eight colors are

W→(1−f(C))·(1−f(M))·(1−f(Y))

C→f(C)·(1−f(M))·(1−f(Y))

M→(1−f(C))·f(M)·(1−f(Y))

Y→(1−f(C))·(1−f(M))·f(Y)

CM→f(C)·f(M)·(1−f(Y))

MY→(1−f(C))·f(M)·f(Y)

YC→f(C)·(1−f(M))·f(Y)

CMY→f(C)·f(M)·f(Y)

Further, when each of three stimulus values of the above-mentioned eightcolors is denoted as follows,

W→(Xw, Yw,Zw)

C→(Xc, Yc,Zc)

M→(Xm,Ym,Zm)

y→(Xy,Yy,Zy)

CM→(Xcm, Ycm,Zcm)

MY→(Xmy, Ymy,Zmy)

YC→(Xyc, Yyc, Zyc)

CMY→(Xcmy, Ycmy, Zcmy)

the three stimulus values X, Y, Z with respect to the input CMY can berepresented as follows. $\begin{pmatrix}X \\Y \\Z\end{pmatrix} = {\begin{pmatrix}{Xw} & {Xc} & {Xm} & {Xy} & {Xcm} & {Xmy} & {Xmc} & {Xcmy} \\{Yw} & {Yc} & {Ym} & {Yy} & {Ycm} & {Ymy} & {Ymc} & {Ycmy} \\{Zw} & {Zc} & {Zm} & {Zy} & {Zcm} & {Zmy} & {Zmc} & {Zcmy}\end{pmatrix} \times {\begin{pmatrix}\left( {1 - {{f(C)} \cdot \left( {1 - {f(M)}} \right) \cdot \left( {1 - {f(Y)}} \right)}} \right. \\{{f(C)} \cdot \left( {1 - {f(M)}} \right) \cdot \left( {1 - {f(Y)}} \right)} \\{\left( {1 - {f(C)}} \right) \cdot {f(M)} \cdot \left( {1 - {f(f)}} \right)} \\{\left( {1 - {f(C)}} \right) \cdot \left( {1 - {f(M)}} \right) \cdot {f(Y)}} \\{{f(C)} \cdot {f(M)} \cdot \left( {1 - {f(Y)}} \right)} \\{\left( {1 - {f(C)}} \right) \cdot {f(M)} \cdot {f(Y)}} \\{{f(C)} \cdot \left( {1 - {f(M)}} \right) \cdot {f(Y)}} \\{{f(C)} \cdot {f(M)} \cdot {f(Y)}}\end{pmatrix}}}$

The conversion of a color space L*a*b* from the three stimulus values X,Y, Z can be realized by a linear calculation.

As for a brightness index L*, the following formula is established.$L^{*} = {{116\left( \frac{Y}{Yn} \right)^{\frac{1}{3}}} - 16}$${{When}\quad \left( \frac{Y}{Yn} \right)} > 0.008856$$L^{*} = {903.29\left( \frac{Y}{Yn} \right)}$${{When}\quad \left( \frac{Y}{Yn} \right)} \leq 0.008856$

In the formula, Y represents the three stimulus values at the printpaper surface and Yn represents the three stimulus values at an entirediffusion reflection surface.

Moreover, as for a chromaticness index a*b*, the following formula isestablished.$a^{*} = {500\left\lbrack {\left( \frac{X}{Xn} \right)^{\frac{1}{3}} - \left( \frac{Y}{Yn} \right)^{\frac{1}{3}}} \right\rbrack}$$b^{*} = {200\left\lbrack {\left( \frac{Y}{Yn} \right)^{\frac{1}{3}} - \left( \frac{Z}{Zn} \right)^{\frac{1}{3}}} \right\rbrack}$${{When}\quad \left( \frac{X}{Xn} \right)} > 0.008856$${{When}\quad \left( \frac{Y}{Yn} \right)} > 0.008856$${{When}\quad \left( \frac{Z}{Zn} \right)} > 0.008856$

In the formula, X, Y, Z represent the three stimulus values at the printpaper surface and Xn, Yn, Zn represent the three stimulus values at anentire diffusion reflection surface. Further, in case where there is avalue 0.008856 or below among X/Xn, Y/Yn, Z/Zn, the term of thecorresponding cubic root is replaced as follows.${7.787\left( \frac{X}{Xn} \right)} + \frac{16}{116}$${7.787\left( \frac{Y}{Yn} \right)} + \frac{16}{116}$${7.787\left( \frac{Z}{Zn} \right)} + \frac{16}{116}$

The chroma T can be obtained from the chromaticness index a*b* by thefollowing formula by utilizing the brightness index L* as the brightnessL.

 T=SQRT{(a*){circumflex over ( )}2+(b*){circumflex over ( )}2}

At a third step ST3, a generation ratio BGR of the black color componentis obtained by using the obtained brightness L and the chroma T.

Firstly, the embodiment of the present invention utilizes the followingconversion formula, not simply coincide the brightness L with the indexof brightness LS.

LS=L+T/2

Moreover, in case where the generation ration BGR becomes the maximum[1] when the index of brightness LS is the same as or below thethreshold value E as well as the BGR becomes the minimum [0] when the LSis the same as or above the threshold value S, and where the curve upongradually decreasing the generation ratio BGR between these values isrepresented by a power function, the generation ratio BGR is representedas follows every case based upon the index of brightness LS.

When LS>S,

BGR=0.0 . . . (1)

When E≦LS≦S,

BGR=pow((S-LS)/(S-E), slope) . . . (2)

when LS<E,

 BGR=1.0 . . . (3)

In these formulas, pow(α,β) represents the β power of α, so that a slopeis an adjusting parameter of the curve. FIG. 4 represents the generationratio BGR and the index of brightness LS having the above-mentionedrelationship, and FIG. 5 briefly shows this relationship in thetwo-dimensional space.

Although the generation ratio of K (BGR) is obtained from therelationship among the formulas (1) to (3) in the embodiment of thepresent invention, it is not limited to these related formulas. In otherwords, it should be noted that the basic precondition may be maintained,this precondition being such that the brighter the data beforeconversion becomes, the more the generation amount of K (Kout)decreases. Accordingly, it is possible that the relationship is the onewhere the generation ratio BGR is kept constant in the predeterminedamount area or that the BGR is varied with respect to thecharacteristics of the curve (power function) in the varying area. Forexample, it may be varied according to the above-mentioned powerfunction within the range from the minimum value to the maximum value ofthe index of brightness LS, or it is possible to utilize y function forthe curve formed upon gradually varying.

Further, the element of the chroma T is added to the index of brightnessin the embodiment of the present invention. By this, the index ofbrightness LS is made small in the area of the small chroma T as well asis made large in the area of the large chroma T. As a result, thegeneration ratio of K (BGR) increases when the chroma T is small tothereby provide characteristics such that the generation amount of K(Kout) increases in the area in the vicinity of gray. Thesecharacteristics mean that the generation amount of K (Kout) is caused tobe increased to make it easy to keep a gray balance except for thebright color area. It is desirable to obtain these effects in theordinary state, but it is possible not to suitably adopt the aforesaidaddition of chroma T to the index of brightness in accordance with thedemand for decreasing the color difference.

In a fourth step ST4, the generation amount of K (Kout) is determinedbased upon the aforesaid undercolor value CMYmin and the generationratio BGR.

Kout=CMYmin* BGR

In this case, the product of the undercolor value CMYmin and thegeneration ratio BGR is utilized. However, the calculation may suitablybe changed. In other words, the generation ratio BGR is only utilized tofinally realize the effect such that the brighter the data beforeconversion becomes, the more the generation amount of K (Kout)decreases.

In a fifth step ST5, an undercolor removal amount UCR is determined asfollows in order to decrease each component of CMY in accordance withthe generation of K.

UCR=K* KC

The mark kc is a parameter for determining the UCR amount from thegeneration amount of K. Normally, this parameter is [0.0] to [1.0]. Thegreater the parameter becomes, the more the amount of CMY decreases.

In a sixth step ST6, each component of CMY such as Cout, Mout, Youtafter the conversion is determined by subtracting the obtainedundercolor removal amount UCR from each of the component of CMY.

Cout=C−UCR

Mout=M−UCR

Yout=Y−UCR

As described above, the generation amount of K (Kout) as well as eachcomponent Cout, Mout, Yout of CMY after the conversion are obtainedbased upon each combination of CMY. FIG. 6 is a graph showing theconversion process as described above.

This conversion relationship should be recorded as a color conversiontable for printing shown in FIG. 7. It should be noted that it becomesthe CMY data at printing operation, while the original input data is notthe CMY data. For example, it is ordinarily RGB data for taking tonecolor data in the case of image processing or image printing by acomputer. Accordingly, two-step color conversion is necessary at theprinting stage such that the color conversion from RGB to CMY is firstlyperformed and then the color conversion from CMY to Cout, Mout, Yout isperformed. FIG. 8 shows a color conversion table for printing in orderto simultaneously execute this two-step color conversion. Detailedly,CMY is obtained by performing the color conversion from RGB to CMY whenthe input data is RGB. Thereafter, the color conversion from CMY toCout, Mout, Yout is performed. The obtained Cout, Mout, Yout arerecorded with RGB to remake the color conversion table. In this way, thecolor conversion table for printing for performing black printing can beformed not only in the case where the input data is RGB but also in thecase of other various color spaces.

Subsequently, a computer system as one example for realizing theabove-mentioned black color generation amount determining method isexplained with reference to FIG. 9. FIG. 9 shows a process for makingthe color conversion table for printing shown in FIG. 8 by a computersystem. The computer system comprises a CPU system 100 for performingcalculation process and disc systems 201 to 203 for reading and writingvarious data files. The CPU system 100 comprises a main calculationdevice, display device, input device, secondary storing device and soon, while the disc systems 201 to 203 comprise an external storingdevice which is a portion of the secondary storing device. A conversionprogram which is executed by the CPU system 100 is stored in thesecondary storing device and the like, whereby it is recorded in thesecondary storing device via floppy disc or CD-ROM or communication lineby a known method.

In such a construction, the CPU system 100 is a means for executing theaforesaid first step ST1 to the sixth step ST6 to form the colorconversion table from CMY to Cout, Mout, Yout on the first disc system201. Subsequently, the CPU system 100 forms the color conversion tablefor printing from RGB to Cout, Mout, Yout on the third disc system 203by matching the recorded color conversion table from RGB to CMY with thecolor conversion table formed on the first disc system 201.

The computer system as described above can be realized in variouscomputers such as from a computer of a personal computer class to alarge-sized computer system.

FIG. 10 shows one example of an image processing printing system foractually performing a printing operation by using the color conversiontable for printing formed as described above. In the image processingprinting system, an image input device 10 inputs tone color data withrespect to a color image to an image processing device 20 which performsimage-processing operation to the tone color data to output to an imageoutput device 30. In this case, the image processing device 20 outputsthe tone color data for displaying and the print data for printing, sothat the aforesaid color conversion table for printing is used formaking the print data.

Specific examples of the image input device 10 include a scanner 11,digital still camera 12 or a video camera 14, while specific examples ofthe image processing device 20 include a computer system comprising acomputer 21, hard disc 22, keyboard 23, CD-ROM drive 24, floppy discdrive 25, modem 26, and the like. Specific examples of the image outputdevice 31 include a printer 31, display 32 or the like. The modem 26 canbe introduced such that it is connected to a public communication linefor connecting to a file server 27 of an external network to downloadthe software or data.

The scanner 11 or the digital still camera 12 as the image input device10 divides the image into pixels of dot matrix type as well as outputstone color data of RGB 256 tones as the image data with respect to eachpixel. The printer 31 as the image output device 30 requires binary tonecolor data of CMYK as the input. Accordingly, the tone color data of 256tones is inputted to perform a predetermined image processing andprinting operation to be outputted as the binary color data in thecomputer 21 as the image processing device 20. Operated in the computer21 is an operating system 21 a into which a printer driver 21 bcorresponding to the printer 31 and a display driver 21 c correspondingto the display 32 are incorporated. An application driver 21 d iscontrolled to perform the processing by the operating system 21 a, andexecutes the display on the display 32 in cooperation with the displaydriver 21 c as well as executes the printing operation in cooperationwith the printer driver 21 b depending on the situation.

It is the case where the print data is formed to the printer 31 as theimage output device 30 that the color conversion table for printing isapplied. Explained hereinafter is the printer 31 in which this printdata is effectively applied.

FIG. 11 shows a schematic construction of the printer 31 which isprovided with a dot printing mechanism comprising a print head 31 aprovided with three print head units, a print head controller 31 b forcontrolling the print head 31 a, a print head lateral moving motor 31 cfor laterally moving the print head 31 a, a paper feed motor 31 d forfeeding a print paper in the longitudinal direction and a printercontroller 31 e serving as an interface to an external apparatus in theprint head controller 31 b, print head lateral moving motor 31 c and thepaper feed motor 31 d, wherein the image printing operation can beperformed in accordance with the print data.

FIG. 12 shows a more specific construction of the print head 31 a. FIG.13 shows the operation upon ejecting ink. Provided at the print head 31a is a minute tube path 31 a 3 extending from a color ink tank 31 a 1 toa nozzle 31 a 2. An ink chamber 31 a 4 is formed at the end portion ofthe tube path 31 a 3. The wall surface of the ink chamber 31 a 4 whichis made of a flexible material is provided with a piezo-element 31 a 5which is an electrostriction element. The piezo-element 31 a 5 deformsthe crystal structure by applying a voltage to perform high-speedelectromechanical energy conversion. The wall surface of the ink chamber31 a 4 is pushed by the deformation of the crystal structure, therebydecreasing the capacity of the ink chamber 31 a 4. As a result, colorink particles of a predetermined amount are gushed out from the nozzle31 a 2 going through the ink chamber 31 a 4. This pump structure isreferred to as a micropump mechanism.

Formed at a single print head unit are independent two nozzle lines 31 a2, each of which is independently supplied with color ink. In thisexample, two lines in the left hand print head unit are used for blackink, single line in the center print head unit is for cyan ink and twolines in the right hand print head unit for magenta and yellowrespectively. In this way, color ink particles are ejected from eachnozzle 31 a 2 by using cyan ink, magenta ink, yellow ink and black inkto reproduce a color image of dot matrix type. The dots are originallyejected here on the assumption that dots of three colors are overlappedwith one another with a predetermined areal ratio as shown in FIG. 3.Based upon this assumption, black color component is added to performprinting operation by the aforesaid process.

In the embodiment of the present invention, the printer 31 of ink jettype adopting the micropump mechanism is explained. However, theembodiment of the present invention is applicable to a printer havinganother color printing mechanism if black printing can be realized.Examples of such a printer include a color printer adopting a pumpmechanism of a bubble jet type or an electrostatic color printer. Inaddition, the present invention is not limited to a printer having acomputer system incorporated between the image input device 10 and theimage output device 30 to perform printing operation, while it isapplicable to a printer in which tone color data is inputted without acomputer system to perform printing operation.

FIG. 14 shows a flowchart when a printing processing is operated in theimage processing printing system having the aforesaid construction. Theprinting processing starts from a condition where the printer driver 21b receives via the operating system 21 a RGB tone color data of the dotmatrix image outputted from the application 21 d.

When receiving via the operating system 21 a RGB tone color data of thedot matrix image in step ST10 as described above, the printer driver 21b performs color conversion from RGB to CMYK with reference to theaforesaid color conversion table for printing. It is not alwaysnecessary for the color conversion table for printing to possess aconversion result as to all of the colors consisting of combinations ofRGB. If there is no corresponding conversion value, the conversionresult may be obtained by performing an interpolation calculation.Further, it may occur that the tone conversion is firstly performedcorresponding in number to tones of the color conversion table forprinting based upon the consideration that the color conversion tablefor printing has less tone number compared to the data beforeconversion, whereupon the color conversion table for printing isreferred after the tone conversion. In the tone conversion in this case,it is necessary to utilize an error diffusion method to prevent colordifference from making great.

To obtain by referring to the color conversion table for printing areCout, Mout, Yout, Kout as described above. In this conversion result,the generation amount of K varies in accordance with brightness even ifthe undercolor value CMYmin is the same. There is a tendency that thebrighter the color is, the more the generation of K decreases.

The condition that the color conversion table for printing is referredto means that the color conversion is only performed. Therefore, it isnecessary to convert the color conversion into binary tone data whichcan be inputted by the printer 31. In step ST30, binarization calledhalftone procedure is executed. The error diffusion method or dithermethod is used in the procedure of binarization to perform toneconversion from the tone color data of CMYK 256 tones to binary tones.

In step ST40, the binarized print data is outputted to the printer 31.The print data is received by the printer controller 31 e of the printer31. The printer controller 31 e relatively scans the print head 31 a onthe paper to eject particulate color ink from each nozzle 31 a 2. Asdescribed above, the generation amount of K is made small with respectto the brighter color when RGB tone color data is color-converted.Further, dot of the black color component appear only in the dark areaas a result of the observation on the paper, thereby not so remarkable.Moreover, the index of brightness LS includes the element of the chromaT, rendering the index of brightness LS great in general. As a result,the generation amount of K (Kout) increases in the area of low chroma T,whereby the gray balance is easy to be kept by increasing the blackcolor component.

Subsequently, an operation of the embodiment of the present inventionhaving the aforesaid construction will be explained.

Assuming that the tone color data read by the scanner 11 is printed bythe printer 31, the application 21 d is firstly operated with theoperating system 21 a being operated in the computer 21, to therebycause the scanner 11 to start reading out. When the read tone color datais received by the application 21 d via the operating system 21 a, apredetermined image processing is performed to select printingprocessing.

When the printing processing is selected, the operating system 21 aoperates the printer driver 21 b. The printer driver 21 b inputs the RGBtone color data as the image data at step ST10, refers the colorconversion table for printing having the structure shown in FIG. 8 fromthe RGB tone value at step ST20 and obtains Cout, Mout, Yout, Kout asthe conversion result. Thereafter, the binarization is performed at stepST30, whereby the binary tone CMYK data is outputted to the printer 31at step ST40.

The printer 31 not only obtains the CMY tone color data having colorcomponents with respect to the RGB tone color data but also performsblack printing including black color component. In this case, theconversion is executed not from the viewpoint of color difference butfrom the viewpoint of unremarkableness of dot, whereby dot of K isunremarkable. For example, in the case of the former example of C:200,M:200, Y:50 which means the components of cyan and magenta are greatlyincluded, the brightness index L* obtained via three stimulus values X,Y, Z is low, so that the index of brightness LS is small even if theelement of the chroma T calculated via the chromaticness index a*b* isadded. As a result, the generation ratio of K (BGR) becomesapproximately 1.0. On the other hand, in the case of C:50, M:50, Y:200having the same undercolor value CMYmin as the former example, thebrightness index L* obtained via the three stimulus values X, Y, Zbecomes high, so that the index of brightness LS is large. As a result,the generation ratio of K (BGR) becomes approximately 0.0. Accordingly,the generation amount of K decreases when the brighter color is used inthe present invention to thereby render the K dot unremarkable in blackprinting including the black color component, while the same amounts ofK components are conventionally generated in the case of the sameundercolor value.

In this way, for performing black printing in a color space for printingcomprising a plurality of approximately equivalent element colors suchas CMY, the CPU system 100 multiplies the undercolor amount CMYmin whichis a common minimum component in the above-mentioned plurality ofelement colors by the predetermined generation ratio BGR to generate ablack color component. In this case, the generation ratio BGR of theblack color component decreases as the data before conversion becomesbrighter, whereby the generation amount Kout of the black colorcomponent is small for the brighter color if the undercolor amountCMYmin is the same. When the printing operation is performed withreference to the color conversion table for printing obtained in thisway, dot corresponding to the black color component is unremarkable.

I claim:
 1. A black color generation amount determining method in blackprinting for generating a black color component in order to performblack printing in a color space for printing comprising a plurality ofapproximately equivalent elementary colors, comprising the steps of:calculating a brightness value of data, expressing an intensity oflight; determining a gray component in said plurality of colors;determining a black color generation ratio, the value of said blackcolor generation ratio varying inversely with said brightness value ofsaid data; and determining a black color generation amount by modifyingsaid gray component according to said black color generation ratio. 2.The black color generation amount determining method in black printingas claimed in claim 1, further comprising determining said graycomponent based upon an undercolor amount, said undercolor amount beinga common minimum component in said plurality of elementary colors. 3.The black color generation amount determining method in black printingas claimed in claim 1, wherein said step of calculating said brightnessvalue is performed with reference to chroma.
 4. The black colorgeneration amount determining method in black printing as claimed inclaim 1, wherein said step of calculating said brightness value isperformed with reference to a table indicating a predefinedcorrespondence relationship between the brightness value and the data.5. The black color generation amount determining method in blackprinting as claimed in claim 1, further comprising determining thegeneration amount of the black color component in the color space forprinting based upon color data comprising a coordinate value of a colorspace different from said color space for printing.
 6. The black colorgeneration amount determining method in black printing as claimed inclaim 1, further comprising using a color conversion table forconverting to said color space for printing from a different colorspace, and wherein said color conversion table includes said determinedblack color component generation amount.
 7. The black color generationamount determining method in black printing as claimed in claim 1,further comprising: obtaining an undercolor value from data colorcomponents, said undercolor value being a common minimum component insaid plurality of elementary colors; calculating chroma of said data;determining said black color generation ratio from said brightness valueand chroma; and determining said black color generation amount basedupon said undercolor value and said black color generation ratio.
 8. Ablack color generation amount determining method in black printing forgenerating a black color component in order to perform black printing ina color space for printing comprising a plurality of approximatelyequivalent elementary colors, comprising the steps of: calculating abrightness value of data; and determining a black color componentgeneration amount in accordance with a gray component in said pluralityof elementary colors, and said calculated brightness value; wherein saidblack color generation amount varies inversely with said calculatedbrightness value; and wherein said step of calculating said brightnessvalue is performed with three stimulus values obtained from theNeugebauer equation, and by a linear conversion of said three stimulusvalues.
 9. A black color generation amount determining apparatusgenerating a black color component used to perform black printing in acolor space comprising a plurality of approximately equivalentelementary colors, comprising: means for calculating a brightness valueof data, expressing an intensity of light; means for determining a graycomponent in said plurality of colors; means for determining a blackcolor generation ratio, the value of said black color generation ratiovarying inversely with said brightness value of said data; and means fordetermining a black color generation amount by modifying said graycomponent according to said black color generation ratio.
 10. The blackcolor generation amount determining apparatus as claimed in claim 9,further comprising means for determining said gray component based uponan undercolor amount, said undercolor amount being a common minimumcomponent in said plurality of elementary colors.
 11. The black colorgeneration amount determining apparatus as claimed in claim 9, whereinsaid calculating of said brightness value is performed with reference tochroma.
 12. The black color generation amount determining apparatus asclaimed in claim 9, wherein said calculating of said brightness value isperformed with reference to a table indicating a predefinedcorrespondence relationship between the brightness value and the data.13. The black color generation amount determining apparatus as claimedin claim 9, further comprising means for determining the generationamount of the black color component in the color space for printingbased upon color data comprising a coordinate value of a color spacedifferent from said color space for printing.
 14. The black colorgeneration amount determining apparatus as claimed in claim 9, furthercomprising a color conversion table for converting to said color spacefrom a different color space, and wherein said color conversion tableincludes said determined black color component generation amount.
 15. Acomputer readable medium with a black color generation program, saidprogram being adapted to enable a computer to determine a generationamount of a black color component in order to perform black printing ina color space comprising a plurality of approximately equivalentelementary colors, said program performing the steps of: calculating abrightness value of data, expressing an intensity of light; determininga gray component in said plurality of colors; determining a black colorgeneration ratio, the value of said black color generation ratio varyinginversely with said brightness value of said data; and determining ablack color generation amount by modifying said gray component accordingto said black color generation ratio.
 16. The computer readable mediumwith a black color generation program as claimed in claim 15, saidprogram further performing the step of determining said gray componentbased upon an undercolor amount, said undercolor amount being a commonminimum component in said plurality of elementary colors.
 17. Thecomputer readable medium with a black color generation program asclaimed in claim 15, wherein said calculating of said brightness valueis performed with reference to chroma.
 18. The computer readable mediumwith a black color generation program as claimed in claim 15, whereinsaid calculating of said brightness value is performed with reference toa table indicating a predefined correspondence relationship between thebrightness value and the data.
 19. The computer readable medium with ablack color generation program as claimed in claim 15, said programfurther comprising a step of determining the generation amount of theblack color component in the color space for printing based upon colordata comprising a coordinate value of a color space different from saidcolor space for printing.
 20. The computer readable medium with a blackcolor generation program as claimed in claim 15, said program furthercomprising a color conversion table for converting to said color spacefrom a different color space, and wherein said color conversion tableincludes said determined black color component generation amount. 21.The computer readable medium with a black color generation program asclaimed in claim 15, said program further comprising the steps of:obtaining an undercolor value from data color components, saidundercolor value being a common minimum component in said plurality ofelementary colors; calculating chroma of said data; determining blackcolor generation ratio from said brightness value and chroma; anddetermining said black color generation amount based upon saidundercolor value and said black color generation ratio.
 22. A blackcolor generation amount determining apparatus generating a black colorcomponent used to perform black printing in a color space comprising aplurality of approximately equivalent elementary colors, comprising:means for calculating a brightness value of data; and means fordetermining a black color component generation amount in accordance witha gray component in said plurality of elementary colors, and saidcalculated brightness value; wherein said black color generation amountvaries inversely with said calculated brightness value; and wherein saidcalculating of said brightness value is performed with three stimulusvalues obtained from the Neugebauer equation, and by a linear conversionof said three stimulus values.
 23. The black color generation amountdetermining apparatus as claimed in claim 9, further comprising: meansfor obtaining an undercolor value from data color components, saidundercolor value being a common minimum component in said plurality ofelementary colors; means for calculating chroma of said data; means fordetermining said black color generation ratio from said brightness valueand chroma; and means for determining said black color generation amountbased upon said undercolor value and said black color generation ratio.24. A computer readable medium with a black color generation program,said program being adapted to enable a computer to determine ageneration amount of a black color component in order to perform blackprinting in a color space comprising a plurality of approximatelyequivalent elementary colors, said program performing the steps of:calculating a brightness value of data; and determining a black colorcomponent generation amount in accordance with a gray component in saidplurality of elementary colors, and the calculated brightness value;wherein said black color generation amount varies inversely with saidcalculated brightness value; and wherein said calculating of saidbrightness value is performed with three stimulus values obtained fromthe Neugebauer equation, and by a linear conversion of said threestimulus values.
 25. An image processor for calculating a black colorgeneration amount in black printing in order to perform black printingin a color space for printing a plurality of approximately equivalentelement colors, comprising: a computer; and a printer driver forgenerating said black color component from image data by: calculating abrightness value of data, expressing an intensity of light; determininga gray component in said plurality of colors; determining a black colorgeneration ratio, the value of said black color generation ratio varyinginversely with said brightness value of said data; and determining ablack color generation amount by modifying said gray component accordingto said black color generation ratio.